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{{short description|Method of transmitting images, often of documents}}
{{Other uses}}
{{Redirect|T.30||T30 (disambiguation)|and|Fax (disambiguation)}}
[[Image:Samfax.jpg|thumb|300px|A [[Samsung]] fax machine from the late 1990s]]
[[Image:Samsung SF-3100 Inkjet Fax Machine.jpg|thumb|upright=1.2|This fax machine from 1999 used relatively new [[inkjet printing]] technology on normal paper.]]
'''Fax''' (short for '''[[facsimile]]'''), sometimes called '''telecopying''' or '''telefax''', is the telephonic transmission of scanned printed material (both text and images), normally to a telephone number connected to a printer or other output device. The original document is scanned with a '''fax machine''' (or a '''telecopier'''), which processes the contents (text or images) as a single fixed graphic image, converting it into a [[bitmap]], and then transmitting it through the telephone system. The receiving fax machine reconverts the coded image, printing a paper copy.<ref>{{cite web|url=http://searchnetworking.techtarget.com/definition/fax|title=What is fax?|last=Rouse|first=Margaret|date=June 2006 |publisher=SearchNetworking |accessdate=25 July 2012}}</ref> For many decades before digital technology became widespread, the scanned data was transmitted as analogue.
[[Image:Panasonic KX-F90.jpg|thumb|upright=1.2|Like many fax machines, this 1990 model used [[thermal printing]] on relatively expensive [[thermal paper]] which came in rolls. The roll was inserted into a compartment in the machine.]]


'''Fax''' (short for '''facsimile'''), sometimes called '''telecopying''' or '''telefax''' (short for '''telefacsimile'''), is the [[telephone|telephonic]] transmission of scanned printed material (both text and images), normally to a telephone number connected to a printer or other output device. The original document is scanned with a '''fax machine''' (or a '''telecopier'''), which processes the contents (text or images) as a single fixed graphic image, converting it into a [[bitmap]], and then transmitting it through the telephone system in the form of audio-frequency tones. The receiving fax machine interprets the tones and reconstructs the image, printing a paper copy.<ref>{{cite web| url=http://searchnetworking.techtarget.com/definition/fax| title=What is fax?| last=Rouse| first=Margaret |date=June 2006 |publisher=SearchNetworking |access-date=25 July 2012}}</ref> Early systems used direct conversions of image darkness to audio tone in a continuous or analog manner. Since the 1980s, most machines transmit an audio-encoded digital representation of the page, using [[data compression]] to transmit areas that are all-white or all-black, more quickly.
==Fax in the 21st century==
Although businesses usually maintain some kind of fax capability, the technology has faced increasing competition from [[Internet]]-based alternatives. Fax machines still retain some advantages, particularly in the transmission of sensitive material which, if sent over the Internet unencrypted, may be vulnerable to interception, without the need for [[telephone tapping]]. In some countries, because [[electronic signature]]s on contracts are not recognized by law while faxed contracts with copies of signatures are, fax machines enjoy continuing support in business.<ref>{{cite web|url=http://www.adamsdrafting.com/2007/11/07/fax-and-scanned-signatures/|title=Enforceability of Fax and Scanned Signature Pages|last=Adams|first=Ken|date=7 November 2007|publisher=AdamsDrafting|accessdate=25 July 2012}}</ref> In Japan, faxes are still used extensively for cultural reasons.<ref>{{cite news|last=Fackler|first=Martin|title=In High-Tech Japan, the Fax Machines Roll On|url=http://www.nytimes.com/2013/02/14/world/asia/in-japan-the-fax-machine-is-anything-but-a-relic.html?pagewanted=1&_r=0&ref=world|accessdate=14 February 2013|newspaper=[[The New York Times]]|date=13 February 2013}}</ref><ref>{{cite web|last=Oi |first=Mariko |url=http://www.bbc.co.uk/news/magazine-19045837 |title=BBC News - Japan and the fax: A love affair |publisher=Bbc.co.uk |date=2012-07-31 |accessdate=2014-02-16}}</ref>


Initially a niche product, fax machines became ubiquitous in offices in the 1980s and 1990s.<ref>{{Cite book |last1=Shapiro |first1=Carl |url=https://books.google.com/books?id=aE_J4Iv_PVEC |title=Information Rules: A Strategic Guide to the Network Economy |last2=Varian |first2=Hal R. |date=1999 |publisher=Harvard Business Press |isbn=978-0-87584-863-1 |pages=13 |language=en}}</ref> They have largely been rendered obsolete by [[Internet]]-based technologies such as [[email]] and the [[World Wide Web]], but are still used in some medical administration and law enforcement settings.<ref name=":0" />
In many corporate environments, freestanding fax machines have been replaced by [[fax server]]s and other computerized systems capable of receiving and storing incoming faxes electronically, and then routing them to users on paper or via an [[email]] (which may be secured). Such systems have the advantage of reducing costs by eliminating unnecessary printouts and reducing the number of inbound analog phone lines needed by an office.

The once ubiquitous fax machine has also begun to disappear from the small office and home office environments. Remotely hosted fax-server services are widely available from VoIP and e-mail providers allowing users to send and receive faxes using their existing e-mail accounts without the need for any hardware or dedicated fax lines. Personal computers have also long been able to handle incoming and outgoing faxes using analogue modems or [[Integrated Services Digital Network|ISDN]], eliminating the need for a stand-alone fax machine. These solutions are often ideally suited for users who only very occasionally need to use fax services.


== History ==
== History ==

=== Wire transmission ===
=== Wire transmission ===
{{see also|Wirephoto}}
Scottish inventor [[Alexander Bain (inventor)|Alexander Bain]] worked on chemical mechanical fax type devices and in 1846 was able to reproduce graphic signs in laboratory experiments. He received the first fax patent in 1843. [[Frederick Bakewell]] made several improvements on Bain's design and demonstrated a telefax machine. The [[Pantelegraph]] was invented by the Italian physicist [[Giovanni Caselli]]. He introduced the first commercial telefax service between Paris and Lyon in 1865, some 11 years before the invention of [[telephone]]s.<ref name="italianunivbio">{{cite web|url=http://www.itisgalileiroma.it/shed/shed0/shed0/caselli.htm |title=Istituto Tecnico Industriale, Rome, Italy. Italian biography of Giovanni Caselli |publisher=Itisgalileiroma.it |date= |accessdate=2014-02-16}}</ref><ref name="hebrewuniversity">[http://chem.ch.huji.ac.il/history/caselli.html The Hebrew University of Jerusalem - Giovanni Caselli biography]</ref>


Scottish inventor [[Alexander Bain (inventor)|Alexander Bain]] worked on chemical-mechanical fax-type devices and in 1846 Bain was able to reproduce graphic signs in laboratory experiments. He received British patent 9745 on May 27, 1843, for his "Electric Printing Telegraph".<ref>{{cite journal |last1=(Staff) |title=Mr. Bain's electric printing telegraph |journal=Mechanics' Magazine |date=20 April 1844 |volume=40 |issue=1080 |pages=268–270 |url=https://books.google.com/books?id=whEFAAAAQAAJ&pg=PA268}}</ref><ref>Bain, Alexander [https://pdfpiw.uspto.gov/.piw?docid=00005957 "Improvement in copying surfaces by electricity"] {{Webarchive|url=https://web.archive.org/web/20210514193846/https://pdfpiw.uspto.gov/.piw?docid=00005957 |date=2021-05-14 }} U.S. patent no. 5,957 (5 December 1848).</ref><ref>{{cite journal |last1=Ruddock |first1=Ivan S. |title=Alexander Bain: The real father of television? |journal=Scottish Local History |date=Summer 2012 |issue=83 |pages=3–13 |url=https://www.slhf.org/sites/default/files/publications/slhf12_alexanderbain.pdf}}</ref> [[Frederick Bakewell]] made several improvements on Bain's design and demonstrated a telefax machine.<ref>Bakewell, Frederick Collier [https://www.nypl.org/sites/default/files/Bakewell-12352.pdf "Electric telegraphs"] English patent no. 12,352 (filed: 2 December 1848; issued: 2 June 1849).</ref><ref>{{cite journal |last1=Bakewell |first1=F.C. |title=On the copying telegraph |journal=American Journal of Science |date=November 1851 |volume=12 |page=278 |url=https://archive.org/details/mobot31753002152392/page/278/mode/2up |series=2nd series}}</ref><ref>{{cite web| url = https://www.gracesguide.co.uk/1851_Great_Exhibition:_Official_Catalogue:_Class_X.:_Frederick_Collier_Bakewell| title = 1851 Great Exhibition: Official Catalogue: Class X.: Frederick Collier Bakewell}}</ref> The [[Pantelegraph]] was invented by the Italian physicist [[Giovanni Caselli]].<ref>Caselli, Giovanni [https://pdfpiw.uspto.gov/.piw?docid=00020698 "Improved pantographic telegraph"] {{Webarchive|url=https://web.archive.org/web/20210514184535/https://pdfpiw.uspto.gov/.piw?docid=00020698 |date=2021-05-14 }} U.S. patent no. 20,698 (June 29, 1858).</ref> He introduced the first commercial telefax service between Paris and Lyon in 1865, some 11 years before the invention of the [[telephone]].<ref name="italianunivbio">{{cite web |url=http://www.itisgalileiroma.it/shed/shed0/shed0/caselli.htm |title=Istituto Tecnico Industriale, Italy. Italian biography of Giovanni Caselli |publisher=Itisgalileiroma.it |access-date=2014-02-16 |archive-date=2020-08-17 |archive-url=https://web.archive.org/web/20200817223601/http://www.itisgalileiroma.it/shed/shed0/shed0/caselli.htm |url-status=dead }}</ref><ref name="hebrewuniversity">{{Cite web|url=http://chem.ch.huji.ac.il/history/caselli.html|archive-url=https://web.archive.org/web/20080506061432/http://chem.ch.huji.ac.il/history/caselli.html |url-status=dead |title=The Hebrew University of Jerusalem – Giovanni Caselli biography|archive-date=May 6, 2008}}</ref>
In 1881, English inventor [[Shelford Bidwell]] constructed the ''scanning phototelegraph'' that was the first telefax machine to scan any two-dimensional original, not requiring manual plotting or drawing. Around 1900, German physicist [[Arthur Korn]] invented the ''[[:de:Bildtelegrafie|Bildtelegraph]]'', widespread in continental Europe especially, since a widely noticed transmission of a wanted-person photograph from Paris to London in 1908, used until the wider distribution of the radiofax. Its main competitors were the ''Bélinographe'' by [[Édouard Belin]] first, then since the 1930s the ''[[Hellschreiber]]'', invented in 1929 by German inventor [[Rudolf Hell]], a pioneer in mechanical image scanning and transmission.


In 1880, English inventor [[Shelford Bidwell]] constructed the ''scanning phototelegraph'' that was the first telefax machine to scan any two-dimensional original, not requiring manual plotting or drawing.<ref>See:
The 1888 invention of the [[telautograph]] by [[Elisha Grey]] marked a further development in fax technology, allowing users to send signatures over long distances, thus allowing the verification of identification or ownership over long distances.<ref>{{cite web|url=http://faxauthority.com/fax-history/|title=The History of Fax – from 1843 to Present Day|publisher=Fax Authority|accessdate=25 July 2012}}</ref>
* {{cite journal |last1=Bidwell |first1=Shelford |title=The photophone |journal=Nature |date=November 18, 1880 |volume=23 |issue=577 |pages=58–59 |doi=10.1038/023058a0 |bibcode=1880Natur..23...58B |s2cid=4127035 |url=https://babel.hathitrust.org/cgi/pt?id=mdp.39015012106640&view=1up&seq=84|doi-access=free }}
* {{cite journal |last1=Bidwell |first1=Shelford |title=Tele-photography |journal=Nature |date=February 10, 1881 |volume=23 |issue=589 |pages=344–346 |doi=10.1038/023344a0 |bibcode=1881Natur..23..344B |url=https://babel.hathitrust.org/cgi/pt?id=mdp.39015012106640&view=1up&seq=374|doi-access=free }}
* {{cite journal |last1=(Staff) |title=Tele-photography |journal=Telegraphic Journal and Electrical Review |date=March 1, 1881 |volume=9 |pages=82–84 |url=https://babel.hathitrust.org/cgi/pt?id=msu.31293007807963&view=1up&seq=144}}</ref> An account of [[Henry Sutton (inventor)#Facsimile|Henry Sutton's "telephane"]] was published in 1896. Around 1900, German physicist [[Arthur Korn]] invented the ''[[Wirephoto|Bildtelegraph]]'', widespread in continental Europe especially following a widely noticed transmission of a wanted-person photograph from Paris to London in 1908,<ref>{{cite book |last1=Korn |first1=Arthur |title=Die Bildtelegraphie im Dienste der Polizei |trans-title=Tele-photography in service to the police |date=1927 |publisher=Ulrich Mosers Buchhandlung |location=Graz, Austria |language=German}}</ref> used until the wider distribution of the radiofax.<ref>{{cite book |last1=Korn |first1=Arthur |title=Elektrisches Fernphotograhie und Ähnliches |trans-title=Electrical transmission of images and similar [systems] |date=1907 |edition=2nd |publisher=S. Hirzel |location=Leipzig, Germany |url=https://books.google.com/books?id=SAUjmgEACAAJ&pg=PA1 |language=German}}</ref><ref>{{cite journal |last1=Korn |first1=Arthur |title=Elektrische Fernphotographie |journal=Elektrotechnische Zeitschrift |date=14 December 1905 |volume=26 |issue=50 |pages=1131–1134 |url=https://books.google.com/books?id=_IhNAAAAYAAJ&pg=PA1131 |trans-title=Electrical tele-photography |language=German}}</ref><ref>{{cite journal |last1=Korn |first1=A. |title=Uber Gebe- und Empfangsapparate zur elektrischen Fernubertragung von Photographien |journal=Physikalische Zeitschrift |date=1904 |volume=5 |issue=4 |pages=113–118 |url=https://babel.hathitrust.org/cgi/pt?id=njp.32101054770829&view=1up&seq=141 |trans-title=On transmitting and receiving apparatuses for the electrical transmission of photographs |language=German}}</ref> Its main competitors were the ''Bélinographe'' by [[Édouard Belin]] first, then since the 1930s the ''[[Hellschreiber]]'', invented in 1929 by German inventor [[Rudolf Hell]], a pioneer in mechanical image scanning and transmission.<ref>{{Cite web |title=Edouard Belin - Belinograph Inventor |url=https://faxauthority.com/biographies/edouard-belin/ |access-date=2023-05-22 |website=Fax Authority |language=en-US}}</ref>

[[File:PSM V44 D062 Sample work of telautograph.jpg|thumb|Input (left) and output (right) of a telautograph transmission]]
The 1888 invention of the [[telautograph]] by [[Elisha Gray]] marked a further development in fax technology, allowing users to send signatures over long distances, thus allowing the verification of identification or ownership over long distances.<ref>Gray, Elisha [https://patents.google.com/patent/US386814A/en "Art of telegraphy"] U.S. patent no. 386,814 (filed: May 31, 1888; issued: July 31, 1888).</ref><ref>Gray, Elisha [https://patents.google.com/patent/US386815A/en "Telautography"] U.S. patent no. 386,815 (filed: June 13, 1888; issued: July 31, 1888).</ref><ref>{{cite web| url=http://faxauthority.com/fax-history/|title=The History of Fax – from 1843 to Present Day |publisher=Fax Authority|access-date=25 July 2012}}</ref>

On May 19, 1924, scientists of the AT&T Corporation "by a new process of transmitting pictures by electricity" sent 15 photographs by telephone from Cleveland to New York City, such photos being suitable for newspaper reproduction. Previously, photographs had been sent over the radio using this process.<ref>[https://news.google.com/newspapers?nid=Fr8DH2VBP9sC&dat=19240520&printsec=frontpage&hl=en "Photos Sent Over Telephone Wire by Cleveland to N.Y.", ''The Gazette'' (Montreal), May 20, 1924, p.10]</ref>

The Western Union "Deskfax" fax machine, announced in 1948, was a compact machine that fit comfortably on a desktop, using special [[spark printer]] paper.<ref name=Ridings1949>G. H. Ridings, [http://massis.lcs.mit.edu/archives/technical/western-union-tech-review/03-1/p017.htm A Facsimile transceiver for Pickup and Delivery of Telegrams] {{Webarchive|url=https://web.archive.org/web/20160208135530/http://massis.lcs.mit.edu/archives/technical/western-union-tech-review/03-1/p017.htm |date=2016-02-08 }}, [http://massis.lcs.mit.edu/archives/technical/western-union-tech-review/03-1/readpg.htm Western Union Technical Review, Vol. 3, No, 1] {{Webarchive|url=https://web.archive.org/web/20160310144615/http://massis.lcs.mit.edu/archives/technical/western-union-tech-review/03-1/readpg.htm |date=2016-03-10 }} (January 1949); page 17-26.</ref>


=== Wireless transmission ===
=== Wireless transmission ===
{{Main|Radiofax}}
{{Main|Radiofax}}
[[File:Krant per fax - Faxed newspaper (4193509648).jpg | upright=1.2|thumb | right | Children read a wirelessly transmitted newspaper in 1938.]]
As a designer for the [[Radio Corporation of America]] (RCA), in 1924, [[Richard H. Ranger]] invented the wireless photoradiogram, or transoceanic [[radiofax|radio facsimile]], the forerunner of today’s "fax" machines. A photograph of President [[Calvin Coolidge]] sent from New York to London on November 29, 1924 became the first photo picture reproduced by transoceanic radio facsimile. Commercial use of Ranger’s product began two years later. Radio fax is still in common use today for transmitting weather charts and information to ships at sea. Also in 1924, [[Herbert E. Ives]] of [[AT&T Corporation]] transmitted and reconstructed the first color facsimile, using color separations. Around 1952 or so, Finch Facsimile, a highly-developed machine, was described in detail in a book; it apparently was never manufactured in quantity.
As a designer for the [[Radio Corporation of America]] (RCA), in 1924, [[Richard H. Ranger]] invented the wireless photoradiogram, or transoceanic [[radiofax|radio facsimile]], the forerunner of today's "fax" machines. A photograph of President [[Calvin Coolidge]] sent from New York to London on November 29, 1924, became the first photo picture reproduced by transoceanic radio facsimile. Commercial use of Ranger's product began two years later. Also in 1924, [[Herbert E. Ives]] of [[AT&T Corporation|AT&T]] transmitted and reconstructed the first color facsimile, a natural-color photograph of silent film star [[Rudolph Valentino]] in period costume, using red, green and blue color separations.<ref name="Sipley">Sipley, Louis Walton (1951). ''A Half Century of Color''. Macmillan.</ref>

Beginning in the late 1930s, the Finch Facsimile system was used to transmit a "radio newspaper" to private homes via commercial AM radio stations and ordinary radio receivers equipped with Finch's printer, which used thermal paper. Sensing a new and potentially golden opportunity, competitors soon entered the field, but the printer and special paper were expensive luxuries, AM radio transmission was very slow and vulnerable to static, and the newspaper was too small. After more than ten years of repeated attempts by Finch and others to establish such a service as a viable business, the public, apparently quite content with its cheaper and much more substantial home-delivered daily newspapers, and with conventional spoken radio bulletins to provide any "hot" news, still showed only a passing curiosity about the new medium.<ref name="Schneider">Schneider, John (2011). [http://www.theradiohistorian.org/Radiofax/newspaper_of_the_air1.htm "The Newspaper of the Air: Early Experiments with Radio Facsimile"]. theradiohistorian.org. Retrieved 2017-05-15.</ref>

By the late 1940s, radiofax receivers were sufficiently miniaturized to be fitted beneath the dashboard of [[Western Union]]'s "Telecar" [[telegram]] delivery vehicles.<ref name=Ridings1949 />


In the 1960s, the United States Army transmitted the first photograph via satellite [[facsimile]] to [[Puerto Rico]] from the [[Deal Test Site]] using the [[Courier 1B|Courier satellite]].
In the 1960s, the [[United States Army]] transmitted the first photograph via satellite [[facsimile]] to [[Puerto Rico]] from the [[Deal Test Site]] using the [[Courier 1B|Courier satellite]].


Radio fax is still in limited use today for transmitting weather charts and information to ships at sea. The closely related technology of [[slow-scan television]] is still used by [[amateur radio]] operators.
{{tone|date=May 2013}}


=== Telephone transmission ===
=== Telephone transmission ===
[[File:Jean Schmidt fax.jpg|thumb|upright|A two-page fax message sent in 2006]]
A landmark year was 1964, in which the Xerox Corporation introduced (and patented) what many consider to be the first commercialized version of the modern fax machine, under the name (LDX) or Long Distance Xerography. This model was superseded two years later with a unit that would truly set the standard for fax machines for years to come. Up until this point facsimile machines were very expensive and hard to operate. In 1966, Xerox released the Magnafax Telecopier, a smaller, 46-pound facsimile machine. This unit was far easier to operate and could be connected to any standard telephone line. This machine was capable of transmitting a letter-sized document in about six minutes. The first sub-minute, digital fax machine was developed by [[Dacom]], which built on digital data compression technology originally developed at [[Lockheed Corporation|Lockheed]] for satellite communication.<ref name="etd.ohiolink.edu">[http://etd.ohiolink.edu/view.cgi/Chung%20Edward%20C.pdf?ohiou1183661772 ''The implementation of a personal computer-based digital facsimile information distribution system'' by Chung, Edward C.]</ref><ref name="Fax 1971, Pages 112-114">''Fax: The Principles and Practice of Facsimile Communication'', Daniel M. Costigan, Chilton Book Company, 1971, pages 112–114, 213, 239</ref>
{{External media|image1=[http://digitalprinting.blogs.xerox.com/wp-content/uploads/sites/3/2012/08/Xerox-LDX-Image.jpg LDX system, Scanner and Printer]|image2=[https://biztechmagazine.com/sites/default/files/Q0416-BT-TOT-Xerox-What.jpg Magnafax Telecopier by Xerox]}}
In 1964, Xerox Corporation introduced (and patented) what many consider to be the first commercialized version of the modern fax machine, under the name (LDX) or Long Distance Xerography. This model was superseded two years later with a unit that would set the standard for fax machines for years to come. Up until this point facsimile machines were very expensive and hard to operate. In 1966, Xerox released the Magnafax Telecopiers, a smaller, {{cvt|46|lb}} facsimile machine. This unit was far easier to operate and could be connected to any standard telephone line. This machine was capable of transmitting a letter-sized document in about six minutes. The first sub-minute, digital fax machine was developed by [[Dacom]], which built on digital data compression technology originally developed at [[Lockheed Corporation|Lockheed]] for satellite communication.<ref name="etd.ohiolink.edu">[https://etd.ohiolink.edu/rws_etd/document/get/ohiou1183661772/inline ''The implementation of a personal computer-based digital facsimile information distribution system''] {{Webarchive|url=https://web.archive.org/web/20160303231649/https://etd.ohiolink.edu/rws_etd/document/get/ohiou1183661772/inline |date=2016-03-03 }} – Edward C. Chung, [[Ohio University]], November 1991, page 2</ref><ref name="Fax 1971, Pages 112-114">''Fax: The Principles and Practice of Facsimile Communication'', Daniel M. Costigan, Chilton Book Company, 1971, pages 112–114, 213, 239</ref>


By the late 1970s, many companies around the world (but especially Japan), entered the fax market. Very shortly after a new wave of more compact, faster and efficient fax machines would hit the market. Xerox continued to refine the fax machine for years after their ground-breaking first machine. But, in later years it would be combined with Copier equipment to create the hybrid machines we have today that copy, scan and fax. Some of the lesser known capabilities of the Xerox fax technologies included their Ethernet enabled Fax Services on their 8000 workstations in the early 1980s.
By the late 1970s, many companies around the world (especially Japanese firms) had entered the fax market. Very shortly after this, a new wave of more compact, faster and efficient fax machines would hit the market. Xerox continued to refine the fax machine for years after their ground-breaking first machine. In later years it would be combined with copier equipment to create the hybrid machines we have today that copy, scan and fax. Some of the lesser known capabilities of the Xerox fax technologies included their Ethernet enabled Fax Services on their 8000 workstations in the early 1980s.


Prior to the introduction of the ubiquitous fax machine, one of the first being the [[ExxonMobil|Exxon]] Qwip<ref>New York Times. [http://www.nytimes.com/1985/02/22/business/an-exxon-sale-to-harris-unit-the-exxon-corporation-said.html An Exxon Sale To Harris Unit], [[New York Times]], February 22, 1985.</ref> in the mid-1970s, facsimile machines worked by optical scanning of a document or drawing spinning on a drum. The reflected light, varying in intensity according to the light and dark areas of the document, was focused on a [[photocell]] so that the current in a circuit varied with the amount of light. This current was used to control a tone generator (a [[modulator]]), the current determining the frequency of the tone produced. This audio tone was then transmitted using an [[acoustic coupler]] (a speaker, in this case) attached to the microphone of a common [[Handset|telephone handset]]. At the receiving end, a handset’s speaker was attached to an acoustic coupler (a microphone), and a [[fax demodulator|demodulator]] converted the varying tone into a variable current that controlled the mechanical movement of a pen or pencil to reproduce the image on a blank sheet of paper on an identical drum rotating at the same rate. A pair of these expensive and bulky machines could only be afforded by companies with a serious need to communicate drawings, design sketches or signed documents between distant locations, such as an office and factory.<ref name="Time-19870831">McCarroll, Thomas. [http://www.time.com/time/magazine/article/0,9171,965337,00.html Just The Fax, Ma'am], [[Time Magazine]], New York, August 31, 1987.</ref> Western Union began a "Faxcimile Telegraphy" service in 1935. Their first coast-to-coast message contained images of [[Mickey Mouse]].
Prior to the introduction of the ubiquitous fax machine, one of the first being the [[ExxonMobil|Exxon]] Qwip<ref>[https://www.nytimes.com/1985/02/22/business/an-exxon-sale-to-harris-unit-the-exxon-corporation-said.html An Exxon Sale To Harris Unit] [[The New York Times]], February 22, 1985.</ref> in the mid-1970s, facsimile machines worked by optical scanning of a document or drawing spinning on a drum. The reflected light, varying in intensity according to the light and dark areas of the document, was focused on a [[photocell]] so that the current in a circuit varied with the amount of light. This current was used to control a tone generator (a [[modulator]]), the current determining the frequency of the tone produced. This audio tone was then transmitted using an [[acoustic coupler]] (a speaker, in this case) attached to the microphone of a common [[Handset|telephone handset]]. At the receiving end, a handset's speaker was attached to an acoustic coupler (a microphone), and a [[fax demodulator|demodulator]] converted the varying tone into a variable current that controlled the mechanical movement of a pen or pencil to reproduce the image on a blank sheet of paper on an identical drum rotating at the same rate.


=== Computer facsimile interface ===
=== Computer facsimile interface ===
In 1985, Dr. [[Ayaz Asmat]], founder of [[GammaLink]], produced the first computer fax board, called [[GammaFax]].
In 1985, [[Hank Magnuski]], founder of [[GammaLink]], produced the first computer fax board, called [[GammaFax]]. Such boards could provide voice telephony via [[Analog Expansion Bus]].<ref>{{cite magazine |last=Perratore |first=Ed |date=September 1992| title= GammaFax MLCP-4/AEB: High-End Fax, Long-Range Potential|magazine=Byte|publisher=McGraw-Hill|issn=0360-5280| volume=17| number=9| pages=82, 84}}</ref>


===In the 21st century===
== Capabilities ==
[[Image:Laserfax.JPG|thumb|Laser fax having a compact, built-in [[laser printer]], 2001.<ref>{{cite web| url = https://download.brother.com/welcome/doc000215/FAX8070_GR_UG_0.pdf| title = Manual of fax machine Brother 8070, see 3rd page}}</ref>]]
There are several indicators of fax [[wikt:capabilities|capabilities]]: Group, class, data transmission rate, and conformance with [[ITU-T]] (formerly [[CCITT]]) recommendations.
Although businesses usually maintain some kind of fax capability, the technology has faced increasing competition from [[Internet]]-based alternatives. In some countries,{{which|date=January 2021}} because [[electronic signature]]s on contracts are not yet [[Electronic signature#Enforceability|recognized by law]], while faxed contracts with copies of signatures are, fax machines enjoy continuing support in business.<ref>{{cite web| url=http://www.adamsdrafting.com/2007/11/07/fax-and-scanned-signatures/ |title=Enforceability of Fax and Scanned Signature Pages|last=Adams| first=Ken| date=7 November 2007|publisher=AdamsDrafting|access-date=25 July 2012}}</ref> In [[Japan]], faxes are still used extensively as of September 2020 for cultural and {{Clarify|reason=|date=May 2024|text=[[wiktionary:grapheme|graphemic]] reasons.}}<ref>{{cite web |last1=Fitzpatrick |first1=Michael |title=Why is hi-tech Japan using cassette tapes and faxes? |url=https://www.bbc.com/news/business-34667380 |work=BBC News |access-date=6 October 2020 |date=3 November 2015}}</ref><ref>{{cite web |last1=Fackler |first1=Martin |title=In High-Tech Japan, the Fax Machines Roll On (Published 2013) |url=https://www.nytimes.com/2013/02/14/world/asia/in-japan-the-fax-machine-is-anything-but-a-relic.html |work=[[The New York Times]] |access-date=6 October 2020 |date=13 February 2013}}</ref><ref>{{cite news |title=Low-tech Japan challenged in working from home amid pandemic |url=https://mainichi.jp/english/articles/20200426/p2g/00m/0na/040000c |website=Mainichi Daily News |publisher=The Mainichi |access-date=6 October 2020 |language=en |date=26 April 2020}}</ref><ref>{{cite web |last1=Osaki |first1=Tomohiro |title=Taro Kono, Japan's administrative reform minister, declares war on faxes |url=https://www.japantimes.co.jp/news/2020/09/27/national/japan-taro-kono-fax-machine-hanko/ |publisher=The Japan Times |access-date=6 October 2020 |date=27 September 2020}}</ref> They are available for sending to both domestic and international recipients from over 81% of all [[convenience stores]] nationwide. Convenience-store fax machines commonly print the slightly re-sized content of the sent fax in the electronic confirmation-slip, in [[A4 paper]] size.<ref>{{cite web |url=http://www.lawson.co.jp/service/counter/fax.html |archive-url=https://web.archive.org/web/20150210112224/http://www.lawson.co.jp/service/counter/fax.html |archive-date=2015-02-10 |title=FAXサービス|サービス|ローソン |language=ja}}</ref><ref>{{cite news |last=Fackler|first=Martin|title=In High-Tech Japan, the Fax Machines Roll On| url=https://www.nytimes.com/2013/02/14/world/asia/in-japan-the-fax-machine-is-anything-but-a-relic.html?pagewanted=1&_r=0&ref=world|access-date=14 February 2013|newspaper=[[The New York Times]]| date=13 February 2013}}</ref><ref>{{cite web|last=Oi |first=Mariko |url=https://www.bbc.co.uk/news/magazine-19045837 |title=Japan and the fax: A love affair |publisher=[[BBC News]] |date=2012-07-31 |access-date=2014-02-16}}</ref> Use of fax machines for reporting cases during the [[COVID-19 pandemic]] has been criticised in Japan for introducing data errors and delays in reporting, slowing response efforts to contain the spread of infections and hindering the transition to [[remote work]].<ref>{{cite web |last1=Osborne |first1=Samuel |title=Japan's reliance on fax machines lambasted by coronavirus doctor |url=https://www.independent.co.uk/news/world/asia/coronavirus-japan-fax-machine-online-hanko-a9501906.html |work=The Independent |access-date=6 October 2020 |language=en |date=6 May 2020}}</ref><ref>{{cite web |last1=Takahashi |first1=Ryusei |title=Tokyo test centers trade fax machines for computers with new coronavirus reporting system |url=https://www.japantimes.co.jp/news/2020/08/04/national/tokyo-coronavirus-testing-faxes/ |publisher=The Japan Times |access-date=6 October 2020 |date=4 August 2020}}</ref><ref>{{cite news |title=Online criticism of outdated paper-and-fax coronavirus infection reports spark change in Japan |url=https://mainichi.jp/english/articles/20200502/p2a/00m/0na/022000c |website=Mainichi Daily News |publisher=The Mainichi |access-date=6 October 2020 |language=en |date=2 May 2020}}</ref>


In many corporate environments, freestanding fax machines have been replaced by [[fax server]]s and other computerized systems capable of receiving and storing incoming faxes electronically, and then routing them to users on paper or via an [[email]] (which may be secured).<ref>{{cite news|last=Coopersmith|first=Jonathan|date=16 June 2021|title=Faxing is old tech. So why is it also growing in popularity?|url=https://www.washingtonpost.com/national/health-science/faxing-is-old-tech-so-why-is-it-also-growing-in-popularity/2019/03/08/d01c638a-2f0b-11e9-86ab-5d02109aeb01_story.html|url-status=live|newspaper=Washington Post|archive-url=https://web.archive.org/web/20230526102333/https://www.washingtonpost.com/national/health-science/faxing-is-old-tech-so-why-is-it-also-growing-in-popularity/2019/03/08/d01c638a-2f0b-11e9-86ab-5d02109aeb01_story.html|archive-date=May 26, 2023}}</ref> Such systems have the advantage of reducing costs by eliminating unnecessary printouts and reducing the number of inbound analog phone lines needed by an office.
Fax machines utilize standard [[PSTN]] lines and telephone numbers.

[[Image:Canon Laser Class 710 fax machine.JPG|thumb|left|Professional laser fax machine for office use with the Super G3 standard for faster fax transmission.]]

The once ubiquitous fax machine has also begun to disappear from the small office and home office environments.{{citation needed|date=January 2021}} Remotely hosted fax-server services are widely available from VoIP and e-mail providers allowing users to send and receive faxes using their existing e-mail accounts without the need for any hardware or dedicated fax lines. Personal computers have also long been able to handle incoming and outgoing faxes using analog modems or [[Integrated Services Digital Network|ISDN]], eliminating the need for a stand-alone fax machine. These solutions are often ideally suited for users who only very occasionally need to use fax services. In July 2017 the United Kingdom's [[National Health Service]] was said to be the world's largest purchaser of fax machines because the digital revolution has largely bypassed it.<ref>{{cite news|title=Digital doldrums: NHS remains world's largest purchaser of fax machines|url=http://www.nationalhealthexecutive.com/Health-Care-News/digital-doldrums-nhs-remains-worlds-largest-purchaser-of-fax-machines|access-date=1 March 2018|publisher=National Health Executive|date=5 July 2017}}</ref> In June 2018 the [[Labour Party (UK)|Labour Party]] said that the NHS had at least 11,620 fax machines in operation<ref>{{cite news |title=NHS 'Struggling To Keep Up' As It Holds On To Thousands Of Fax Machines |url=https://www.huffingtonpost.co.uk/entry/nhs-fax-machines-labour_uk_5b1e5f83e4b09d7a3d7508e7 |access-date=11 June 2018 |work=Huffington Post |date=11 June 2018}}</ref> and in December the [[Department of Health and Social Care]] said that no more fax machines could be bought from 2019 and that the existing ones must be replaced by secure email by March 31, 2020.<ref>{{cite news |title=NHS told to ditch 'absurd' fax machines |url=https://www.bbc.co.uk/news/uk-46497526 |access-date=9 December 2018 |work=BBC |date=9 December 2018}}</ref>

[[Leeds Teaching Hospitals NHS Trust]], generally viewed as digitally advanced in the NHS, was engaged in a process of removing its fax machines in early 2019. This involved quite a lot of [[e-fax]] solutions because of the need to communicate with pharmacies and nursing homes which may not have access to the NHS email system and may need something in their paper records.<ref>{{cite news |title=OK, it's early 2019. Has Leeds Hospital finally managed to 'axe the fax'? Um, yes and no |url=https://www.theregister.co.uk/2019/02/04/leeds_hospital_nhs_trust_efax/ |access-date=5 February 2019 |work=[[The Register]] |date=4 February 2019 |first=Rebecca |last=Hill}}</ref>

In 2018 two-thirds of Canadian doctors reported that they primarily used fax machines to communicate with other doctors. Faxes are still seen as safer and more secure and electronic systems are often unable to communicate with each other.<ref>{{cite news |title=Why are fax machines still the norm in 21st-century health care? |url=https://www.theglobeandmail.com/opinion/article-why-are-fax-machines-still-the-norm-in-21st-century-health-care/ |access-date=21 April 2019 |newspaper=Globe and Mail |date=11 June 2018}}</ref>

Hospitals are the leading users for fax machines in the United States where some doctors prefer fax machines over emails, often due to concerns about accidentally violating [[HIPAA]].<ref name=":0">{{cite magazine |title=The Fax Is Not Yet Obsolete |url=https://www.theatlantic.com/technology/archive/2018/11/why-people-still-use-fax-machines/576070/ |access-date=30 January 2023 |magazine=[[The Atlantic]] |date=18 November 2018 |archive-url=https://web.archive.org/web/20181118233042/https://www.theatlantic.com/technology/archive/2018/11/why-people-still-use-fax-machines/576070/ |archive-date=2018-11-18 |first=Sophie |last=Haigney}}</ref>

== Capabilities ==
There are several indicators of fax capabilities: group, class, data transmission rate, and conformance with [[ITU-T]] (formerly [[CCITT]]) recommendations. Since the 1968 [[Carterfone decision]], most fax machines have been designed to connect to standard [[PSTN]] lines and telephone numbers.


=== Group ===
=== Group ===
Line 48: Line 76:


* Group 1 faxes conform to the ITU-T Recommendation T.2. Group 1 faxes take six minutes to transmit a single page, with a vertical resolution of 96 [[scan line]]s per inch. Group 1 fax machines are obsolete and no longer manufactured.
* Group 1 faxes conform to the ITU-T Recommendation T.2. Group 1 faxes take six minutes to transmit a single page, with a vertical resolution of 96 [[scan line]]s per inch. Group 1 fax machines are obsolete and no longer manufactured.
* Group 2 faxes conform to the ITU-T Recommendations T.30 and T.3. Group 2 faxes take three minutes to transmit a single page, with a vertical resolution of 96 scan lines per inch. Group 2 fax machines are almost obsolete, and are no longer manufactured. Group 2 fax machines can interoperate with Group 3 fax machines.
* Group 2 faxes conform to the ITU-T Recommendations T.3 and T.30. Group 2 faxes take three minutes to transmit a single page, with a vertical resolution of 96 scan lines per inch. Group 2 fax machines are almost obsolete, and are no longer manufactured. Group 2 fax machines can interoperate with Group 3 fax machines.


==== Digital ====
==== Digital ====
[[File:Dacom DFC-10.jpg|thumb|300 px|The Dacom DFC-10—the first digital fax machine.<ref name="etd.ohiolink.edu"/>]]
[[File:Dacom DFC-10.jpg|thumb|upright=1.2|The Dacom DFC-10—the first digital fax machine<ref name="etd.ohiolink.edu"/>]]
[[File:Faxchip.jpg|thumb|300 px|The chip in a fax machine. Only about one quarter of the length is shown. The thin line in the middle consists of photosensitive [[pixel]]s. The read-out circuit is at left.]]
[[File:Faxchip.jpg|thumb|upright=1.2|The chip in a fax machine. Only about one quarter of the length is shown. The thin line in the middle consists of photosensitive [[pixel]]s. The read-out circuit is at left.]]
A major breakthrough in the development of the modern facsimile system was the result of digital technology. Where the analog signal from scanners was digitized and then compressed, resulting in the ability to transmit high rates of data across standard phone lines. The first digital fax machine was the [[Dacom]] Rapidfax first sold in late 1960s, which incorporated digital data compression technology developed by [[Lockheed Corporation|Lockheed]] for transmission of images from satellites.<ref name="etd.ohiolink.edu"/><ref name="Fax 1971, Pages 112-114"/>
A major breakthrough in the development of the modern facsimile system was the result of digital technology, where the analog signal from scanners was digitized and then compressed, resulting in the ability to transmit high rates of data across standard phone lines. The first digital fax machine was the [[Dacom]] Rapidfax first sold in late 1960s, which incorporated digital data compression technology developed by [[Lockheed Corporation|Lockheed]] for transmission of images from satellites.<ref name="etd.ohiolink.edu"/><ref name="Fax 1971, Pages 112-114"/>


Group 3 and 4 faxes are digital formats, and take advantage of digital compression methods to greatly reduce transmission times.
Group 3 and 4 faxes are digital formats and take advantage of digital compression methods to greatly reduce transmission times.


* Group 3 faxes conform to the ITU-T Recommendations T.30 and T.4. Group 3 faxes take between six and fifteen seconds to transmit a single page (not including the initial time for the fax machines to handshake and synchronize). The horizontal and vertical resolutions are allowed by the T.4 standard to vary among a set of fixed resolutions:
* Group 3 faxes conform to the ITU-T Recommendations T.30 and T.4. Group&nbsp;3 faxes take between 6 and 15&nbsp;seconds to transmit a single page (not including the initial time for the fax machines to handshake and synchronize). The horizontal and vertical resolutions are allowed by the T.4 standard to vary among a set of fixed resolutions:
** Horizontal: 100 scan lines per inch
** Horizontal: 100 scan lines per inch
*** Vertical: 100 scan lines per inch ("Basic")
*** Vertical: 100 scan lines per inch ("Basic")
Line 68: Line 96:
** Horizontal: 400 or 408 scan lines per inch
** Horizontal: 400 or 408 scan lines per inch
*** Vertical: 400 or 391 scan lines per inch ("Ultrafine")
*** Vertical: 400 or 391 scan lines per inch ("Ultrafine")
* Group 4 faxes conform to the ITU-T Recommendations T.563, T.503, T.521, T.6, T.62, T.70, T.411 to T.417. They are designed to operate over 64 kbit/s digital [[ISDN]] circuits. The allowed resolutions, a superset of those in the T.4 recommendation, are specified in the T.6 recommendation.<ref name="T6"/>
* Group 4 faxes conform to the ITU-T Recommendations T.563, T.503, T.521, T.6, T.62, T.70, T.411 to T.417. They are designed to operate over 64&nbsp;kbit/s digital [[ISDN]] circuits. The allowed resolutions, a superset of those in the T.4 recommendation, are specified in the T.6 recommendation.<ref name="T6"/>


Fax Over IP (FoIP) can transmit and receive pre-digitized documents at near realtime speeds using [[T.38 ITU-T recommendation|ITU-T recommendation T.38]] to send digitised images over an [[IP network]] using [[JPEG]] compression. T.38 is designed to work with [[VoIP]] services and often supported by [[analog telephone adapter]]s used by legacy fax machines that need to connect through a VoIP service. Scanned documents are limited to the amount of time the user takes to load the document in a scanner and for the device to process a digital file. The resolution can vary from as little as 150 DPI to 9600 DPI or more. This type of faxing is not related to the e-mail to fax service that still uses fax modems at least one way.
Fax Over IP ([[FoIP]]) can transmit and receive pre-digitized documents at near-realtime{{vague|date=March 2022}} speeds using [[T.38 ITU-T recommendation|ITU-T recommendation T.38]] to send digitised images over an [[IP network]] using [[JPEG]] compression. T.38 is designed to work with [[VoIP]] services and often supported by [[analog telephone adapter]]s used by legacy fax machines that need to connect through a VoIP service. Scanned documents are limited to the amount of time the user takes to load the document in a scanner and for the device to process a digital file. The resolution can vary from as little as 150&nbsp;DPI to 9600&nbsp;DPI or more. This type of faxing is not related to the e-mail–to–fax service that still uses fax modems at least one way.


=== Class ===
=== Class ===
Computer modems are often designated by a particular fax class, which indicates how much processing is offloaded from the computer's CPU to the fax modem.
Computer modems are often designated by a particular fax class, which indicates how much processing is offloaded from the computer's CPU to the fax modem.


* Class 1 fax devices do fax data transfer where the T.4/T.6 data compression and T.30 session management are performed by software on a controlling computer. This is described in ITU-T recommendation T.31.<ref name=peterson2000>{{cite book
* Class 1 (also known as Class 1.0) fax devices do fax data transfer, while the T.4/T.6 data compression and T.30 session management are performed by software on a controlling computer. This is described in ITU-T recommendation T.31.<ref name=peterson2000>{{cite book| first=Kerstin Day | last=Peterson | year=2000| title=Business telecom systems: a guide to choosing the best technologies and services| pages=191–192| publisher=Focal Press| isbn=1578200415| url=https://books.google.com/books?id=W79R0niNU5wC&pg=PA191| access-date=2011-04-02 }}</ref>
* What is commonly known as "Class 2" is an unofficial class of fax devices that perform T.30 session management themselves, but the T.4/T.6 data compression is performed by software on a controlling computer. Implementations of this "class" are based on draft versions of the standard that eventually significantly evolved to become Class&nbsp;2.0.<ref>{{Cite web | url = https://legacy.hylafax.org/site1//Modems/Supra/class2.html | title = Supra Technical Support Bulletin: Class 2 Fax Commands For Supra Faxmodems | date = June 19, 1992 | access-date = March 23, 2019}}</ref> All implementations of "Class 2" are manufacturer-specific.<ref name="Multi-Tech">{{Cite web | url = https://www.multitech.com/documents/publications/manuals/s000239.pdf | title = Fax Developer's Guide: Classes 2 and 2.0/2.1 | date = 2017 | publisher=Multi-Tech Systems | access-date = March 23, 2019}}</ref>
| first=Kerstin Day | last=Peterson | year=2000
* Class 2.0 is the official ITU-T version of Class&nbsp;2 and is commonly known as Class&nbsp;2.0 to differentiate it from many manufacturer-specific implementations of what is commonly known as "Class&nbsp;2". It uses a different but standardized command set than the various manufacturer-specific implementations of "Class&nbsp;2". The relevant ITU-T recommendation is T.32.<ref name="Multi-Tech"/>
| title=Business telecom systems: a guide to choosing the best technologies and services
* Class 2.1 is an improvement of Class&nbsp;2.0 that implements faxing over V.34 (33.6&nbsp;kbit/s), which boosts faxing speed from fax classes "2" and 2.0, which are limited to 14.4&nbsp;kbit/s.<ref name="Multi-Tech"/> The relevant ITU-T recommendation is T.32 Amendment&nbsp;1.<ref name="Multi-Tech"/> Class&nbsp;2.1 fax devices are referred to as "super&nbsp;G3".
| pages=191&ndash;192
| publisher=Focal Press
| isbn=1578200415
| url=http://books.google.com/books?id=W79R0niNU5wC&pg=PA191
| accessdate=2011-04-02 }}</ref>
* Class 2 fax devices perform T.30 session management themselves, but the T.4/T.6 data compression is performed by software on a controlling computer. The relevant ITU-T recommendation is T.32.<ref name=peterson2000/>
* Class 2.0 is different from Class 2.
* Class 2.1 is an improvement of Class 2.0. Class 2.1 fax devices are referred to as "super G3"; they seem to be a little faster than Class 1/2/2.0.
* Class 3 fax devices are responsible for virtually the entire fax session, given little more than a phone number and the text to send (including rendering ASCII text as a raster image). These devices are not common.


=== Data transmission rate ===
=== Data transmission rate ===
Several different telephone line modulation techniques are used by fax machines. They are negotiated during the fax-[[modem]] [[handshaking|handshake]], and the fax devices will use the highest data rate that both fax devices support, usually a minimum of 14.4 kbit/s for Group 3 fax.
Several different telephone-line modulation techniques are used by fax machines. They are negotiated during the fax-[[modem]] [[Handshake (computing)|handshake]], and the fax devices will use the highest data rate that both fax devices support, usually a minimum of 14.4&nbsp;kbit/s for Group&nbsp;3 fax.


:{| class="wikitable"
:{| class="wikitable"
!ITU Standard
!ITU standard
!Released Date
!Released date
!Data Rates (bit/s)
!Data rates (bit/s)
!Modulation Method
!Modulation method
|-
|-
|[[List of ITU-T V-Series Recommendations#Interfaces and voiceband modems|V.27]]
|[[ITU-T V.27|V.27]]
|1988
|1988
|4800, 2400
|4800, 2400
|[[phase-shift keying|PSK]]
|[[phase-shift keying|PSK]]
|-
|-
|[[List of ITU-T V-Series Recommendations#Interfaces and voiceband modems|V.29]]
|[[ITU-T V.29|V.29]]
|1988
|1988
|9600, 7200, 4800
|9600, 7200, 4800
|[[quadrature amplitude modulation|QAM]]
|[[quadrature amplitude modulation|QAM]]
|-
|-
|[[List of ITU-T V-Series Recommendations#Interfaces and voiceband modems|V.17]]
|[[ITU-T V.17|V.17]]
|1991
|1991
|14,400; 12,000; 9600; 7200
|{{val|14,400}}, {{val|12,000}}, 9600, 7200
|[[trellis modulation|TCM]]
|[[trellis modulation|TCM]]
|-
|-
|[[List of ITU-T V-Series Recommendations#Interfaces and voiceband modems|V.34]]
|[[ITU-T V.34|V.34]]
|1994
|1994
|28,800
|{{val|28,800}}
|[[quadrature amplitude modulation|QAM]]
|[[quadrature amplitude modulation|QAM]]
|-
|-
|[[List of ITU-T V-Series Recommendations#Interfaces and voiceband modems|V.34bis]]
|[[ITU-T V.34bis|V.34bis]]
|1998
|1998
|33,600
|{{val|33,600}}
|[[quadrature amplitude modulation|QAM]]
|[[quadrature amplitude modulation|QAM]]
|-
|-
|[[ISDN]]
|[[ISDN]]
|1986
|
|64,000
|{{val|64,000}}
|digital
|digital
|}
|}


Note that "Super Group 3" faxes use V.34bis modulation that allows a data rate of up to 33.6 kbit/s.
"Super Group&nbsp;3" faxes use V.34bis modulation that allows a data rate of up to 33.6&nbsp;kbit/s.


=== Compression ===
=== Compression ===
As well as specifying the resolution (and allowable physical size of the image being faxed), the ITU-T T.4 recommendation specifies two compression methods for decreasing the amount of data that needs to be transmitted between the fax machines to transfer the image. The two methods defined in T.4 are:<ref name="T4">{{cite web|url=http://www.itu.int/rec/T-REC-T.4/en|title=T.4: Standardization of Group 3 facsimile terminals for document transmission|publisher=ITU-T|date=2003-07|accessdate=2013-12-28}}</ref>
As well as specifying the resolution (and allowable physical size) of the image being faxed, the ITU-T&nbsp;T.4 recommendation specifies two compression methods for decreasing the amount of data that needs to be transmitted between the fax machines to transfer the image. The two methods defined in T.4 are:<ref name="T4">{{cite web |url=http://www.itu.int/rec/T-REC-T.4/en |title=T.4: Standardization of Group 3 facsimile terminals for document transmission |publisher=ITU-T |date=2011-03-14 |access-date=2013-12-28}}</ref>
*[[Modified Huffman coding|Modified Huffman]] (MH), and
* [[Modified Huffman coding|Modified Huffman]] (MH).
*[[Modified READ]] (MR) (''Relative Element Address Designate''<ref>[http://ieeexplore.ieee.org/xpl/login.jsp?tp=&arnumber=1456020&url=http%3A%2F%2Fieeexplore.ieee.org%2Fiel5%2F5%2F31291%2F01456020.pdf%3Farnumber%3D1456020 ''International digital facsimile coding standards],'' Hunter, R., and Robinson, A.H., Proceedings of the IEEE Volume 68 Issue 7, pp 854–867, July 1980</ref>), optional
* [[Modified READ]] (MR) (''Relative Element Address Designate''<ref>{{cite journal | url=https://ieeexplore.ieee.org/document/1456020 | doi=10.1109/PROC.1980.11751 | title=International digital facsimile coding standards | year=1980 | last1=Hunter | first1=R. | last2=Robinson | first2=A.H. | journal=Proceedings of the IEEE | volume=68 | issue=7 | pages=854–867 | s2cid=46403372 }}</ref>), optional.
An additional method is specified in T.6:<ref name="T6">{{cite web|url=http://www.itu.int/rec/T-REC-T.6/en|title=T.6: Facsimile coding schemes and coding control functions for Group 4 facsimile apparatus|publisher=ITU-T|date=November 1988|accessdate=2013-12-28}}</ref>
An additional method is specified in T.6:<ref name="T6">{{cite web| url=http://www.itu.int/rec/T-REC-T.6/en |title=T.6: Facsimile coding schemes and coding control functions for Group 4 facsimile apparatus |publisher=ITU-T |date=November 1988 |access-date=2013-12-28}}</ref>
*[[Group 4 compression|Modified Modified READ]] (MMR)
* [[Group 4 compression|Modified Modified READ]] (MMR).
Later, other compression techniques were added as options to ITU-T recommendation T.30, such as the more efficient [[JBIG]] (T.82, T.85) for bi-level content, and [[JPEG]] (T.81), T.43, [[Mixed raster content|MRC]] (T.44), and T.45 for grayscale, palette, and colour content.<ref name="T30">{{cite web|url=http://www.itu.int/rec/T-REC-T.30|title=T.30: Procedures for document facsimile transmission in the general switched telephone network|publisher=ITU-T|date=2005-09|accessdate=2013-12-28}}</ref> Fax machines can negotiate at the start of the T.30 session to use the best technique implemented on both sides.
Later, other compression techniques were added as options to ITU-T recommendation T.30, such as the more efficient [[JBIG]] (T.82, T.85) for bi-level content, and [[JPEG]] (T.81), T.43, [[Mixed raster content|MRC]] (T.44), and T.45 for grayscale, palette, and colour content.<ref name="T30">{{cite web |url=http://www.itu.int/rec/T-REC-T.30 |title=T.30: Procedures for document facsimile transmission in the general switched telephone network |publisher=ITU-T |date=2014-05-15 |access-date=2013-12-28}}</ref> Fax machines can negotiate at the start of the T.30 session to use the best technique implemented on both sides.


==== Modified Huffman ====
==== Modified Huffman ====
Line 143: Line 163:


==== Modified READ ====
==== Modified READ ====
Modified READ (MR), specified as an optional two-dimensional coding scheme in T.4, encodes the first scanned line using MH.<ref name="T4"/> The next line is compared to the first, the differences determined, and then the differences are encoded and transmitted.<ref name="T4"/> This is effective as most lines differ little from their predecessor. This is not continued to the end of the fax transmission, but only for a limited number of lines until the process is reset and a new 'first line' encoded with MH is produced. This limited number of lines is to prevent errors propagating throughout the whole fax, as the standard does not provide for error-correction. MR is an optional facility, and some fax machines do not use MR in order to minimise the amount of computation required by the machine. The limited number of lines is two for 'Standard' resolution faxes, and four for 'Fine' resolution faxes.
Modified READ, specified as an optional two-dimensional coding scheme in T.4, encodes the first scanned line using MH.<ref name="T4"/> The next line is compared to the first, the differences determined, and then the differences are encoded and transmitted.<ref name="T4"/> This is effective, as most lines differ little from their predecessor. This is not continued to the end of the fax transmission, but only for a limited number of lines until the process is reset, and a new "first line" encoded with MH is produced. This limited number of lines is to prevent errors propagating throughout the whole fax, as the standard does not provide for error correction. This is an optional facility, and some fax machines do not use MR in order to minimise the amount of computation required by the machine. The limited number of lines is 2 for "Standard"-resolution faxes, and 4 for "Fine"-resolution faxes.


==== Modified Modified READ ====
==== Modified Modified READ ====
{{Main|Group 4 compression}}
{{Main|Group 4 compression}}
The ITU-T T.6 recommendation adds a further compression type of Modified Modified READ (MMR), which simply allows for a greater number of lines to be coded by MR than in T.4.<ref name="T6"/> This is because T.6 makes the assumption that the transmission is over a circuit with a low number of line errors such as digital ISDN. In this case, there is no maximum number of lines for which the differences are encoded.
The ITU-T T.6 recommendation adds a further compression type of Modified Modified READ (MMR), which simply allows a greater number of lines to be coded by MR than in T.4.<ref name="T6"/> This is because T.6 makes the assumption that the transmission is over a circuit with a low number of line errors, such as digital [[Integrated Services Digital Network|ISDN]]. In this case, the number of lines for which the differences are encoded is not limited.


==== JBIG ====
==== JBIG ====


In 1999, ITU-T recommendation T.30 added [[JBIG]] (ITU-T T.82) as another [[lossless]] [[bi-level]] compression algorithm, or more precisely a "fax profile" subset of JBIG (ITU-T T.85). JBIG-compressed pages result in 20% to 50% faster transmission than MMR-compressed pages, and up to 30-times faster transmission if the page includes [[halftone]] images.
In 1999, ITU-T recommendation T.30 added [[JBIG]] (ITU-T T.82) as another [[lossless]] [[Binary image|bi-level]] compression algorithm, or more precisely a "fax profile" subset of JBIG (ITU-T T.85). JBIG-compressed pages result in 20% to 50% faster transmission than MMR-compressed pages, and up to 30 times faster transmission if the page includes [[halftone]] images.


[[JBIG]] performs [[adaptive compression]], that is both the encoder and decoder collect statistical information about the transmitted image from the pixels transmitted so far, in order to predict the probability for each next pixel being either black or white. For each new pixel, JBIG looks at ten nearby, previously transmitted pixels. It counts, how often in the past the next pixel has been black or white in the same neighborhood, and estimates from that the probability distribution of the next pixel. This is fed into an [[arithmetic coder]], which adds only a small fraction of a bit to the output sequence if the more probable pixel is then encountered.
[[JBIG]] performs [[adaptive compression]], that is, both the encoder and decoder collect statistical information about the transmitted image from the pixels transmitted so far, in order to predict the probability for each next pixel being either black or white. For each new pixel, JBIG looks at ten nearby, previously transmitted pixels. It counts, how often in the past the next pixel has been black or white in the same neighborhood, and estimates from that the probability distribution of the next pixel. This is fed into an [[arithmetic coder]], which adds only a small fraction of a bit to the output sequence if the more probable pixel is then encountered.


The ITU-T T.85 "fax profile" constrains some optional features of the full JBIG standard, such that codecs do not have to keep data about more than the last three pixel rows of an image in memory at any time. This allows the streaming of "endless" images, where the height of the image may not be known until the last row is transmitted.
The ITU-T T.85 "fax profile" constrains some optional features of the full JBIG standard, such that codecs do not have to keep data about more than the last three pixel rows of an image in memory at any time. This allows the streaming of "endless" images, where the height of the image may not be known until the last row is transmitted.


ITU-T T.30 allows fax machines to negotiate one of two options of the T.85 "fax profile":
ITU-T T.30 allows fax machines to negotiate one of two options of the T.85 "fax profile":
* In "basic mode", the JBIG encoder must split the image into horizontal stripes of 128 lines (parameter L0=128), and restart the arithmetic encoder for each stripe.
* In "basic mode", the JBIG encoder must split the image into horizontal stripes of 128 lines (parameter L0&nbsp;=&nbsp;128) and restart the arithmetic encoder for each stripe.
* In "option mode", there is no such constraint.
* In "option mode", there is no such constraint.


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=== Typical characteristics ===
=== Typical characteristics ===
Group 3 fax machines transfer one or a few printed or handwritten pages per minute in black-and-white (bitonal) at a [[Optical resolution|resolution]] of 204×98 (normal) or 204×196 (fine) dots per square inch. The transfer rate is 14.4&nbsp;kbit/s or higher for modems and some fax machines, but fax machines support speeds beginning with 2400 bit/s and typically operate at 9600 bit/s. The transferred image formats are called [[ITU-T]] (formerly CCITT) fax group 3 or 4.
Group 3 fax machines transfer one or a few printed or handwritten pages per minute in black-and-white (bitonal) at a [[Optical resolution|resolution]] of 204×98 (normal) or 204×196 (fine) dots per square inch. The transfer rate is 14.4&nbsp;kbit/s or higher for modems and some fax machines, but fax machines support speeds beginning with 2400 bit/s and typically operate at 9600 bit/s. The transferred image formats are called [[ITU-T]] (formerly CCITT) fax group 3 or 4. Group 3 faxes have the [[Filename extension|suffix]] <code>.g3</code> and the [[MIME type]] <code>image/g3fax</code>.


The most basic fax mode transfers black and white colors only. The original page is scanned in a resolution of 1728 [[pixel]]s/line and 1145 lines/page (for [[A4 paper size|A4]]). The resulting raw data is [[data compression|compressed]] using a modified [[Huffman coding|Huffman code]] optimized for written text, achieving average compression factors of around 20. Typically a page needs 10&nbsp;s for transmission, instead of about 3 minutes for the same uncompressed raw data of 1728×1145 bits at a speed of 9600&nbsp;bit/s. The compression method uses a Huffman codebook for run lengths of black and white runs in a single scanned line, and it can also use the fact that two adjacent scanlines are usually quite similar, saving bandwidth by encoding only the differences.
The most basic fax mode transfers in black and white only. The original page is scanned in a resolution of 1728 [[pixel]]s/line and 1145 lines/page (for [[A4 paper size|A4]]). The resulting raw data is [[data compression|compressed]] using a modified [[Huffman coding|Huffman code]] optimized for written text, achieving average compression factors of around 20. Typically a page needs 10&nbsp;s for transmission, instead of about three minutes for the same uncompressed raw data of 1728×1145 bits at a speed of 9600&nbsp;bit/s. The compression method uses a Huffman codebook for run lengths of black and white runs in a single scanned line, and it can also use the fact that two adjacent scanlines are usually quite similar, saving bandwidth by encoding only the differences.


Fax classes denote the way fax programs interact with fax hardware. Available classes include Class 1, Class 2, Class 2.0 and 2.1, and Intel CAS. Many modems support at least class 1 and often either Class 2 or Class 2.0. Which is preferable to use depends on factors such as hardware, software, modem firmware, and expected use.
Fax classes denote the way fax programs interact with fax hardware. Available classes include Class 1, Class 2, Class 2.0 and 2.1, and Intel CAS. Many modems support at least class 1 and often either Class 2 or Class 2.0. Which is preferable to use depends on factors such as hardware, software, modem firmware, and expected use.


===Printing process===
Fax machines from the 1970s to the 1990s often used direct [[thermal printer]]s with rolls of thermal paper as their printing technology, but since the mid-1990s there has been a transition towards plain-paper faxes:- [[thermal transfer printer]]s, [[inkjet printer]]s and laser printers.
Fax machines from the 1970s to the 1990s often used direct [[thermal printer]]s with rolls of thermal paper as their printing technology, but since the mid-1990s there has been a transition towards plain-paper faxes: [[thermal transfer printer]]s, [[inkjet printer]]s and [[Laser printing|laser printers]].


One of the advantages of inkjet printing is that inkjets can affordably print in [[color]]; therefore, many of the inkjet-based fax machines claim to have color fax capability. There is a standard called ITU-T30e (formally ITU-T Recommendation T.30 Annex E <ref>{{cite web|author=tsbmail |url=http://www.itu.int/rec/T-REC-T.30-200509-I/en |title=T.30 : Procedures for document facsimile transmission in the general switched telephone network |publisher=Itu.int |date= |accessdate=2014-02-16}}</ref>) for faxing in color; unfortunately, it is not widely supported, so many of the color fax machines can only fax in color to machines from the same manufacturer.
One of the advantages of inkjet printing is that inkjets can affordably print in [[color]]; therefore, many of the inkjet-based fax machines claim to have color fax capability. There is a standard called ITU-T30e (formally ITU-T Recommendation T.30 Annex E <ref>{{cite web| author=tsbmail |url=http://www.itu.int/rec/T-REC-T.30-200509-I/en |title=T.30 : Procedures for document facsimile transmission in the general switched telephone network |publisher=Itu.int |access-date=2014-02-16}}</ref>) for faxing in color; however, it is not widely supported, so many of the color fax machines can only fax in color to machines from the same manufacturer.{{citation needed|date=October 2018}}


=== Stroke speed ===
=== Stroke speed ===
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=== Fax paper ===
=== Fax paper ===
[[File:ThermalPaperG3-TMG.JPG|thumb|[[Thermal paper|Paper]] roll for [[thermal transfer printer]] fax machine]]
[[File:ThermalPaperG3-TMG.JPG|thumb|[[Thermal paper|Paper]] roll for [[thermal printing|direct thermal]] fax machine]]
As a precaution, thermal fax paper is typically not accepted in archives or as documentary evidence in some courts of law unless photocopied. This is because the image-forming coating is eradicable and brittle, and it tends to detach from the medium after a long time in storage.<ref>"4.12 Filing rules: 19.Newspaper extracts or thermal facsimile paper should not be preserved as archives. Such extracts should be photocopied and the copy preserved. The original can then be destroyed." Office of Corporate & Legal Affairs, University College Cork, Ireland</ref>
As a precaution, thermal fax paper is typically not accepted in archives or as documentary evidence in some courts of law unless photocopied. This is because the image-forming coating is eradicable and brittle, and it tends to detach from the medium after a long time in storage.<ref>"4.12 Filing rules: 19.Newspaper extracts or thermal facsimile paper should not be preserved as archives. Such extracts should be photocopied and the copy preserved. The original can then be destroyed." Office of Corporate & Legal Affairs, University College Cork, Ireland</ref>

=== Fax tone ===

{{expand section|reason=there are others|date=October 2023}}

A CNG tone is an 1100&nbsp;Hz tone transmitted by a fax machine when it calls another fax machine. Fax tones can cause complications when implementing [[fax over IP]].


== Internet fax ==
== Internet fax ==
{{see also|Internet fax}}
{{see also|Internet fax}}
{{unreferenced section|date=December 2013}}
{{more citations needed section|date=June 2017}}
One popular alternative is to subscribe to an [[internet fax]] service, allowing users to send and receive faxes from their [[personal computer]]s using an existing [[email account]]. No software, fax server or fax machine is needed. Faxes are received as attached [[Tagged Image File Format|TIFF]] or [[Portable Document Format|PDF]] files, or in proprietary formats that require the use of the service provider's software. Faxes can be sent or retrieved from anywhere at any time that a user can get internet access. Some services offer secure faxing to comply with stringent [[Health Insurance Portability and Accountability Act|HIPAA]] and [[Gramm–Leach–Bliley Act]] requirements to keep medical information and financial information private and secure. Utilizing a fax service provider does not require paper, a dedicated fax line, or consumable resources.<ref>{{cite web|url=http://blog.efax.com/blog/online-fax-2/five-reasons-to-adopt-online-fax|title=Online Fax vs Traditional Fax|date=16 May 2013|publisher=eFax|accessdate=8 December 2013}}</ref>
One popular alternative is to subscribe to an [[Internet fax]] service, allowing users to send and receive faxes from their [[personal computer]]s using an existing [[email account]]. No software, fax server or fax machine is needed. Faxes are received as attached [[TIFF]] or [[PDF]] files, or in proprietary formats that require the use of the service provider's software. Faxes can be sent or retrieved from anywhere at any time that a user can get Internet access. Some services offer secure faxing to comply with stringent [[Health Insurance Portability and Accountability Act|HIPAA]] and [[Gramm–Leach–Bliley Act]] requirements to keep medical information and financial information private and secure. Utilizing a fax service provider does not require paper, a dedicated fax line, or consumable resources.<ref>{{cite web|url=http://blog.efax.com/blog/online-fax-2/five-reasons-to-adopt-online-fax| title=Online Fax vs Traditional Fax|date=16 May 2013|publisher=eFax|access-date=8 December 2013}}</ref>


Another alternative to a physical fax machine is to make use of computer [[software]] which allows people to send and receive faxes using their own computers, utilizing [[fax server]]s and [[unified messaging]]. A virtual (email) fax can be printed out and then signed and scanned back to computer before being emailed. Also the sender can attach a digital signature to the document file.
Another alternative to a physical fax machine is to make use of computer [[software]] which allows people to send and receive faxes using their own computers, utilizing [[fax server]]s and [[unified messaging]]. A virtual (email) fax can be printed out and then signed and scanned back to computer before being emailed. Also the sender can attach a digital signature to the document file.

With the surging popularity of mobile phones, virtual fax machines can now be downloaded as applications for Android and iOS. These applications make use of the phone's internal camera to scan fax documents for upload or they can import from various cloud services.

==Related standards==
* T.4 is the umbrella specification for fax. It specifies the standard image sizes, two forms of image-data compression (encoding), the image-data format, and references, T.30 and the various modem standards.
* T.6 specifies a compression scheme that reduces the time required to transmit an image by roughly 50-percent.
* T.30 specifies the procedures that a sending and receiving terminal use to set up a fax call, determine the image size, encoding, and transfer speed, the demarcation between pages, and the termination of the call. T.30 also references the various modem standards.
* [[ITU-T V.21|V.21]], [[ITU-T V.27ter|V.27ter]], [[ITU-T V.29|V.29]], [[ITU-T V.17|V.17]], [[ITU-T V.34|V.34]]: ITU modem standards used in facsimile. The first three were ratified prior to 1980, and were specified in the original T.4 and T.30 standards. V.34 was published for fax in 1994.<ref>{{cite web| url=http://www.itwissen.info/definition/lexikon/V-34-V-34.html |title=V.34| website=www.itwissen.info|access-date=2018-01-12| archive-url=https://web.archive.org/web/20161228020937/http://www.itwissen.info/definition/lexikon/V-34-V-34.html| archive-date=2016-12-28|url-status=dead}}</ref>
* [[T.37 (ITU-T recommendation)|T.37]] The ITU standard for sending a fax-image file via e-mail to the intended recipient of a fax.
* [[T.38]] The ITU standard for sending Fax over IP (FoIP).
* [[G.711]] pass through - this is where the T.30 fax call is carried in a VoIP call encoded as audio. This is sensitive to network [[packet loss]], [[jitter]] and clock synchronization. When using voice high-compression encoding techniques such as, but not limited to, [[G.729]], some fax tonal signals may not be correctly transported across the packet network.
* {{IETF RFC|3362|link=no}} image/t38 MIME-type
*[https://hylafax.sourceforge.io/sslfax.php SSL Fax] An emerging standard that allows a telephone based fax session to negotiate a fax transfer over the internet, but only if both sides support the standard. The standard is partially based on T.30 and is being developed by Hylafax+ developers.


== See also ==
== See also ==
{{Portal|Telecommunications}}
{{Portal|Telecommunication|Telephones}}
{{div col|colwidth=20em}}
{{colbegin|2}}
* [[3D Fax]]
* [[Black fax]]
* [[Black fax]]
* [[Called subscriber identification]] (CSID)
* [[Called subscriber identification]] (CSID)
Line 201: Line 242:
* [[Faxlore]]
* [[Faxlore]]
* [[Fultograph]]
* [[Fultograph]]
* [[Image scanner]]
* [[Internet fax]]
* [[Internet fax]]
* [[Junk fax]]
* [[Junk fax]]
Line 208: Line 250:
* [[Telautograph]]
* [[Telautograph]]
* [[Telex]]
* [[Telex]]
* [[Teletex]]
* [[Transmitting Subscriber Identification]] (TSID)
* [[Transmitting Subscriber Identification]] (TSID)
* [[Wirephoto]]
{{colend}}
{{div col end}}


== References ==
== References ==
{{Reflist|2}}
{{Reflist}}

==Further reading==
* Coopersmith, Jonathan, ''Faxed: The Rise and Fall of the Fax Machine'' (Johns Hopkins University Press, 2015) 308 pp.
* "[https://books.google.com/books?id=f50oAQAAMAAJ Transmitting Photographs by Telegraph]", ''[[Scientific American]]'' article, 12 May 1877, p.&nbsp;297


== External links ==
== External links ==
{{Wiktionary|fax|facsimile}}
{{Wiktionary|fax|facsimile}}
{{Wiktionary|facsimile}}
{{Commons category|Fax machines}}
{{Commons category|Fax machines}}
* [http://www.garretwilson.com/essays/computers/group3fax.html Group 3 Facsimile Communication] a '97 essay with technical details on compression and error codes, and call establishment and release.
* [http://www.garretwilson.com/essays/computers/group3fax.html Group 3 Facsimile Communication]—A '97 essay with technical details on compression and error codes, and call establishment and release.
* [http://www.itu.int/rec/T-REC-T.30/en ITU T.30 Recommendation]
* [http://www.itu.int/rec/T-REC-T.30/en ITU T.30 Recommendation]


{{URI scheme}}
{{URI schemes}}
{{Telecommunications}}
{{Telecommunications}}
{{Authority control}}


[[Category:Fax| ]]
[[Category:Fax| ]]
[[Category:1843 introductions]]
[[Category:American inventions]]
[[Category:American inventions]]
[[Category:Computer peripherals]]
[[Category:Computer peripherals]]

Latest revision as of 05:59, 21 November 2024

This fax machine from 1999 used relatively new inkjet printing technology on normal paper.
Like many fax machines, this 1990 model used thermal printing on relatively expensive thermal paper which came in rolls. The roll was inserted into a compartment in the machine.

Fax (short for facsimile), sometimes called telecopying or telefax (short for telefacsimile), is the telephonic transmission of scanned printed material (both text and images), normally to a telephone number connected to a printer or other output device. The original document is scanned with a fax machine (or a telecopier), which processes the contents (text or images) as a single fixed graphic image, converting it into a bitmap, and then transmitting it through the telephone system in the form of audio-frequency tones. The receiving fax machine interprets the tones and reconstructs the image, printing a paper copy.[1] Early systems used direct conversions of image darkness to audio tone in a continuous or analog manner. Since the 1980s, most machines transmit an audio-encoded digital representation of the page, using data compression to transmit areas that are all-white or all-black, more quickly.

Initially a niche product, fax machines became ubiquitous in offices in the 1980s and 1990s.[2] They have largely been rendered obsolete by Internet-based technologies such as email and the World Wide Web, but are still used in some medical administration and law enforcement settings.[3]

History

[edit]

Wire transmission

[edit]

Scottish inventor Alexander Bain worked on chemical-mechanical fax-type devices and in 1846 Bain was able to reproduce graphic signs in laboratory experiments. He received British patent 9745 on May 27, 1843, for his "Electric Printing Telegraph".[4][5][6] Frederick Bakewell made several improvements on Bain's design and demonstrated a telefax machine.[7][8][9] The Pantelegraph was invented by the Italian physicist Giovanni Caselli.[10] He introduced the first commercial telefax service between Paris and Lyon in 1865, some 11 years before the invention of the telephone.[11][12]

In 1880, English inventor Shelford Bidwell constructed the scanning phototelegraph that was the first telefax machine to scan any two-dimensional original, not requiring manual plotting or drawing.[13] An account of Henry Sutton's "telephane" was published in 1896. Around 1900, German physicist Arthur Korn invented the Bildtelegraph, widespread in continental Europe especially following a widely noticed transmission of a wanted-person photograph from Paris to London in 1908,[14] used until the wider distribution of the radiofax.[15][16][17] Its main competitors were the Bélinographe by Édouard Belin first, then since the 1930s the Hellschreiber, invented in 1929 by German inventor Rudolf Hell, a pioneer in mechanical image scanning and transmission.[18]

Input (left) and output (right) of a telautograph transmission

The 1888 invention of the telautograph by Elisha Gray marked a further development in fax technology, allowing users to send signatures over long distances, thus allowing the verification of identification or ownership over long distances.[19][20][21]

On May 19, 1924, scientists of the AT&T Corporation "by a new process of transmitting pictures by electricity" sent 15 photographs by telephone from Cleveland to New York City, such photos being suitable for newspaper reproduction. Previously, photographs had been sent over the radio using this process.[22]

The Western Union "Deskfax" fax machine, announced in 1948, was a compact machine that fit comfortably on a desktop, using special spark printer paper.[23]

Wireless transmission

[edit]
Children read a wirelessly transmitted newspaper in 1938.

As a designer for the Radio Corporation of America (RCA), in 1924, Richard H. Ranger invented the wireless photoradiogram, or transoceanic radio facsimile, the forerunner of today's "fax" machines. A photograph of President Calvin Coolidge sent from New York to London on November 29, 1924, became the first photo picture reproduced by transoceanic radio facsimile. Commercial use of Ranger's product began two years later. Also in 1924, Herbert E. Ives of AT&T transmitted and reconstructed the first color facsimile, a natural-color photograph of silent film star Rudolph Valentino in period costume, using red, green and blue color separations.[24]

Beginning in the late 1930s, the Finch Facsimile system was used to transmit a "radio newspaper" to private homes via commercial AM radio stations and ordinary radio receivers equipped with Finch's printer, which used thermal paper. Sensing a new and potentially golden opportunity, competitors soon entered the field, but the printer and special paper were expensive luxuries, AM radio transmission was very slow and vulnerable to static, and the newspaper was too small. After more than ten years of repeated attempts by Finch and others to establish such a service as a viable business, the public, apparently quite content with its cheaper and much more substantial home-delivered daily newspapers, and with conventional spoken radio bulletins to provide any "hot" news, still showed only a passing curiosity about the new medium.[25]

By the late 1940s, radiofax receivers were sufficiently miniaturized to be fitted beneath the dashboard of Western Union's "Telecar" telegram delivery vehicles.[23]

In the 1960s, the United States Army transmitted the first photograph via satellite facsimile to Puerto Rico from the Deal Test Site using the Courier satellite.

Radio fax is still in limited use today for transmitting weather charts and information to ships at sea. The closely related technology of slow-scan television is still used by amateur radio operators.

Telephone transmission

[edit]
A two-page fax message sent in 2006
External images
image icon LDX system, Scanner and Printer
image icon Magnafax Telecopier by Xerox

In 1964, Xerox Corporation introduced (and patented) what many consider to be the first commercialized version of the modern fax machine, under the name (LDX) or Long Distance Xerography. This model was superseded two years later with a unit that would set the standard for fax machines for years to come. Up until this point facsimile machines were very expensive and hard to operate. In 1966, Xerox released the Magnafax Telecopiers, a smaller, 46 lb (21 kg) facsimile machine. This unit was far easier to operate and could be connected to any standard telephone line. This machine was capable of transmitting a letter-sized document in about six minutes. The first sub-minute, digital fax machine was developed by Dacom, which built on digital data compression technology originally developed at Lockheed for satellite communication.[26][27]

By the late 1970s, many companies around the world (especially Japanese firms) had entered the fax market. Very shortly after this, a new wave of more compact, faster and efficient fax machines would hit the market. Xerox continued to refine the fax machine for years after their ground-breaking first machine. In later years it would be combined with copier equipment to create the hybrid machines we have today that copy, scan and fax. Some of the lesser known capabilities of the Xerox fax technologies included their Ethernet enabled Fax Services on their 8000 workstations in the early 1980s.

Prior to the introduction of the ubiquitous fax machine, one of the first being the Exxon Qwip[28] in the mid-1970s, facsimile machines worked by optical scanning of a document or drawing spinning on a drum. The reflected light, varying in intensity according to the light and dark areas of the document, was focused on a photocell so that the current in a circuit varied with the amount of light. This current was used to control a tone generator (a modulator), the current determining the frequency of the tone produced. This audio tone was then transmitted using an acoustic coupler (a speaker, in this case) attached to the microphone of a common telephone handset. At the receiving end, a handset's speaker was attached to an acoustic coupler (a microphone), and a demodulator converted the varying tone into a variable current that controlled the mechanical movement of a pen or pencil to reproduce the image on a blank sheet of paper on an identical drum rotating at the same rate.

Computer facsimile interface

[edit]

In 1985, Hank Magnuski, founder of GammaLink, produced the first computer fax board, called GammaFax. Such boards could provide voice telephony via Analog Expansion Bus.[29]

In the 21st century

[edit]
Laser fax having a compact, built-in laser printer, 2001.[30]

Although businesses usually maintain some kind of fax capability, the technology has faced increasing competition from Internet-based alternatives. In some countries,[which?] because electronic signatures on contracts are not yet recognized by law, while faxed contracts with copies of signatures are, fax machines enjoy continuing support in business.[31] In Japan, faxes are still used extensively as of September 2020 for cultural and graphemic reasons.[clarification needed][32][33][34][35] They are available for sending to both domestic and international recipients from over 81% of all convenience stores nationwide. Convenience-store fax machines commonly print the slightly re-sized content of the sent fax in the electronic confirmation-slip, in A4 paper size.[36][37][38] Use of fax machines for reporting cases during the COVID-19 pandemic has been criticised in Japan for introducing data errors and delays in reporting, slowing response efforts to contain the spread of infections and hindering the transition to remote work.[39][40][41]

In many corporate environments, freestanding fax machines have been replaced by fax servers and other computerized systems capable of receiving and storing incoming faxes electronically, and then routing them to users on paper or via an email (which may be secured).[42] Such systems have the advantage of reducing costs by eliminating unnecessary printouts and reducing the number of inbound analog phone lines needed by an office.

Professional laser fax machine for office use with the Super G3 standard for faster fax transmission.

The once ubiquitous fax machine has also begun to disappear from the small office and home office environments.[citation needed] Remotely hosted fax-server services are widely available from VoIP and e-mail providers allowing users to send and receive faxes using their existing e-mail accounts without the need for any hardware or dedicated fax lines. Personal computers have also long been able to handle incoming and outgoing faxes using analog modems or ISDN, eliminating the need for a stand-alone fax machine. These solutions are often ideally suited for users who only very occasionally need to use fax services. In July 2017 the United Kingdom's National Health Service was said to be the world's largest purchaser of fax machines because the digital revolution has largely bypassed it.[43] In June 2018 the Labour Party said that the NHS had at least 11,620 fax machines in operation[44] and in December the Department of Health and Social Care said that no more fax machines could be bought from 2019 and that the existing ones must be replaced by secure email by March 31, 2020.[45]

Leeds Teaching Hospitals NHS Trust, generally viewed as digitally advanced in the NHS, was engaged in a process of removing its fax machines in early 2019. This involved quite a lot of e-fax solutions because of the need to communicate with pharmacies and nursing homes which may not have access to the NHS email system and may need something in their paper records.[46]

In 2018 two-thirds of Canadian doctors reported that they primarily used fax machines to communicate with other doctors. Faxes are still seen as safer and more secure and electronic systems are often unable to communicate with each other.[47]

Hospitals are the leading users for fax machines in the United States where some doctors prefer fax machines over emails, often due to concerns about accidentally violating HIPAA.[3]

Capabilities

[edit]

There are several indicators of fax capabilities: group, class, data transmission rate, and conformance with ITU-T (formerly CCITT) recommendations. Since the 1968 Carterfone decision, most fax machines have been designed to connect to standard PSTN lines and telephone numbers.

Group

[edit]

Analog

[edit]

Group 1 and 2 faxes are sent in the same manner as a frame of analog television, with each scanned line transmitted as a continuous analog signal. Horizontal resolution depended upon the quality of the scanner, transmission line, and the printer. Analog fax machines are obsolete and no longer manufactured. ITU-T Recommendations T.2 and T.3 were withdrawn as obsolete in July 1996.

  • Group 1 faxes conform to the ITU-T Recommendation T.2. Group 1 faxes take six minutes to transmit a single page, with a vertical resolution of 96 scan lines per inch. Group 1 fax machines are obsolete and no longer manufactured.
  • Group 2 faxes conform to the ITU-T Recommendations T.3 and T.30. Group 2 faxes take three minutes to transmit a single page, with a vertical resolution of 96 scan lines per inch. Group 2 fax machines are almost obsolete, and are no longer manufactured. Group 2 fax machines can interoperate with Group 3 fax machines.

Digital

[edit]
The Dacom DFC-10—the first digital fax machine[26]
The chip in a fax machine. Only about one quarter of the length is shown. The thin line in the middle consists of photosensitive pixels. The read-out circuit is at left.

A major breakthrough in the development of the modern facsimile system was the result of digital technology, where the analog signal from scanners was digitized and then compressed, resulting in the ability to transmit high rates of data across standard phone lines. The first digital fax machine was the Dacom Rapidfax first sold in late 1960s, which incorporated digital data compression technology developed by Lockheed for transmission of images from satellites.[26][27]

Group 3 and 4 faxes are digital formats and take advantage of digital compression methods to greatly reduce transmission times.

  • Group 3 faxes conform to the ITU-T Recommendations T.30 and T.4. Group 3 faxes take between 6 and 15 seconds to transmit a single page (not including the initial time for the fax machines to handshake and synchronize). The horizontal and vertical resolutions are allowed by the T.4 standard to vary among a set of fixed resolutions:
    • Horizontal: 100 scan lines per inch
      • Vertical: 100 scan lines per inch ("Basic")
    • Horizontal: 200 or 204 scan lines per inch
      • Vertical: 100 or 98 scan lines per inch ("Standard")
      • Vertical: 200 or 196 scan lines per inch ("Fine")
      • Vertical: 400 or 391 (note not 392) scan lines per inch ("Superfine")
    • Horizontal: 300 scan lines per inch
      • Vertical: 300 scan lines per inch
    • Horizontal: 400 or 408 scan lines per inch
      • Vertical: 400 or 391 scan lines per inch ("Ultrafine")
  • Group 4 faxes conform to the ITU-T Recommendations T.563, T.503, T.521, T.6, T.62, T.70, T.411 to T.417. They are designed to operate over 64 kbit/s digital ISDN circuits. The allowed resolutions, a superset of those in the T.4 recommendation, are specified in the T.6 recommendation.[48]

Fax Over IP (FoIP) can transmit and receive pre-digitized documents at near-realtime[vague] speeds using ITU-T recommendation T.38 to send digitised images over an IP network using JPEG compression. T.38 is designed to work with VoIP services and often supported by analog telephone adapters used by legacy fax machines that need to connect through a VoIP service. Scanned documents are limited to the amount of time the user takes to load the document in a scanner and for the device to process a digital file. The resolution can vary from as little as 150 DPI to 9600 DPI or more. This type of faxing is not related to the e-mail–to–fax service that still uses fax modems at least one way.

Class

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Computer modems are often designated by a particular fax class, which indicates how much processing is offloaded from the computer's CPU to the fax modem.

  • Class 1 (also known as Class 1.0) fax devices do fax data transfer, while the T.4/T.6 data compression and T.30 session management are performed by software on a controlling computer. This is described in ITU-T recommendation T.31.[49]
  • What is commonly known as "Class 2" is an unofficial class of fax devices that perform T.30 session management themselves, but the T.4/T.6 data compression is performed by software on a controlling computer. Implementations of this "class" are based on draft versions of the standard that eventually significantly evolved to become Class 2.0.[50] All implementations of "Class 2" are manufacturer-specific.[51]
  • Class 2.0 is the official ITU-T version of Class 2 and is commonly known as Class 2.0 to differentiate it from many manufacturer-specific implementations of what is commonly known as "Class 2". It uses a different but standardized command set than the various manufacturer-specific implementations of "Class 2". The relevant ITU-T recommendation is T.32.[51]
  • Class 2.1 is an improvement of Class 2.0 that implements faxing over V.34 (33.6 kbit/s), which boosts faxing speed from fax classes "2" and 2.0, which are limited to 14.4 kbit/s.[51] The relevant ITU-T recommendation is T.32 Amendment 1.[51] Class 2.1 fax devices are referred to as "super G3".

Data transmission rate

[edit]

Several different telephone-line modulation techniques are used by fax machines. They are negotiated during the fax-modem handshake, and the fax devices will use the highest data rate that both fax devices support, usually a minimum of 14.4 kbit/s for Group 3 fax.

ITU standard Released date Data rates (bit/s) Modulation method
V.27 1988 4800, 2400 PSK
V.29 1988 9600, 7200, 4800 QAM
V.17 1991 14400, 12000, 9600, 7200 TCM
V.34 1994 28800 QAM
V.34bis 1998 33600 QAM
ISDN 1986 64000 digital

"Super Group 3" faxes use V.34bis modulation that allows a data rate of up to 33.6 kbit/s.

Compression

[edit]

As well as specifying the resolution (and allowable physical size) of the image being faxed, the ITU-T T.4 recommendation specifies two compression methods for decreasing the amount of data that needs to be transmitted between the fax machines to transfer the image. The two methods defined in T.4 are:[52]

An additional method is specified in T.6:[48]

Later, other compression techniques were added as options to ITU-T recommendation T.30, such as the more efficient JBIG (T.82, T.85) for bi-level content, and JPEG (T.81), T.43, MRC (T.44), and T.45 for grayscale, palette, and colour content.[54] Fax machines can negotiate at the start of the T.30 session to use the best technique implemented on both sides.

Modified Huffman

[edit]

Modified Huffman (MH), specified in T.4 as the one-dimensional coding scheme, is a codebook-based run-length encoding scheme optimised to efficiently compress whitespace.[52] As most faxes consist mostly of white space, this minimises the transmission time of most faxes. Each line scanned is compressed independently of its predecessor and successor.[52]

Modified READ

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Modified READ, specified as an optional two-dimensional coding scheme in T.4, encodes the first scanned line using MH.[52] The next line is compared to the first, the differences determined, and then the differences are encoded and transmitted.[52] This is effective, as most lines differ little from their predecessor. This is not continued to the end of the fax transmission, but only for a limited number of lines until the process is reset, and a new "first line" encoded with MH is produced. This limited number of lines is to prevent errors propagating throughout the whole fax, as the standard does not provide for error correction. This is an optional facility, and some fax machines do not use MR in order to minimise the amount of computation required by the machine. The limited number of lines is 2 for "Standard"-resolution faxes, and 4 for "Fine"-resolution faxes.

Modified Modified READ

[edit]

The ITU-T T.6 recommendation adds a further compression type of Modified Modified READ (MMR), which simply allows a greater number of lines to be coded by MR than in T.4.[48] This is because T.6 makes the assumption that the transmission is over a circuit with a low number of line errors, such as digital ISDN. In this case, the number of lines for which the differences are encoded is not limited.

JBIG

[edit]

In 1999, ITU-T recommendation T.30 added JBIG (ITU-T T.82) as another lossless bi-level compression algorithm, or more precisely a "fax profile" subset of JBIG (ITU-T T.85). JBIG-compressed pages result in 20% to 50% faster transmission than MMR-compressed pages, and up to 30 times faster transmission if the page includes halftone images.

JBIG performs adaptive compression, that is, both the encoder and decoder collect statistical information about the transmitted image from the pixels transmitted so far, in order to predict the probability for each next pixel being either black or white. For each new pixel, JBIG looks at ten nearby, previously transmitted pixels. It counts, how often in the past the next pixel has been black or white in the same neighborhood, and estimates from that the probability distribution of the next pixel. This is fed into an arithmetic coder, which adds only a small fraction of a bit to the output sequence if the more probable pixel is then encountered.

The ITU-T T.85 "fax profile" constrains some optional features of the full JBIG standard, such that codecs do not have to keep data about more than the last three pixel rows of an image in memory at any time. This allows the streaming of "endless" images, where the height of the image may not be known until the last row is transmitted.

ITU-T T.30 allows fax machines to negotiate one of two options of the T.85 "fax profile":

  • In "basic mode", the JBIG encoder must split the image into horizontal stripes of 128 lines (parameter L0 = 128) and restart the arithmetic encoder for each stripe.
  • In "option mode", there is no such constraint.

Matsushita Whiteline Skip

[edit]

A proprietary compression scheme employed on Panasonic fax machines is Matsushita Whiteline Skip (MWS). It can be overlaid on the other compression schemes, but is operative only when two Panasonic machines are communicating with one another. This system detects the blank scanned areas between lines of text, and then compresses several blank scan lines into the data space of a single character. (JBIG implements a similar technique called "typical prediction", if header flag TPBON is set to 1.)

Typical characteristics

[edit]

Group 3 fax machines transfer one or a few printed or handwritten pages per minute in black-and-white (bitonal) at a resolution of 204×98 (normal) or 204×196 (fine) dots per square inch. The transfer rate is 14.4 kbit/s or higher for modems and some fax machines, but fax machines support speeds beginning with 2400 bit/s and typically operate at 9600 bit/s. The transferred image formats are called ITU-T (formerly CCITT) fax group 3 or 4. Group 3 faxes have the suffix .g3 and the MIME type image/g3fax.

The most basic fax mode transfers in black and white only. The original page is scanned in a resolution of 1728 pixels/line and 1145 lines/page (for A4). The resulting raw data is compressed using a modified Huffman code optimized for written text, achieving average compression factors of around 20. Typically a page needs 10 s for transmission, instead of about three minutes for the same uncompressed raw data of 1728×1145 bits at a speed of 9600 bit/s. The compression method uses a Huffman codebook for run lengths of black and white runs in a single scanned line, and it can also use the fact that two adjacent scanlines are usually quite similar, saving bandwidth by encoding only the differences.

Fax classes denote the way fax programs interact with fax hardware. Available classes include Class 1, Class 2, Class 2.0 and 2.1, and Intel CAS. Many modems support at least class 1 and often either Class 2 or Class 2.0. Which is preferable to use depends on factors such as hardware, software, modem firmware, and expected use.

Printing process

[edit]

Fax machines from the 1970s to the 1990s often used direct thermal printers with rolls of thermal paper as their printing technology, but since the mid-1990s there has been a transition towards plain-paper faxes: thermal transfer printers, inkjet printers and laser printers.

One of the advantages of inkjet printing is that inkjets can affordably print in color; therefore, many of the inkjet-based fax machines claim to have color fax capability. There is a standard called ITU-T30e (formally ITU-T Recommendation T.30 Annex E [55]) for faxing in color; however, it is not widely supported, so many of the color fax machines can only fax in color to machines from the same manufacturer.[citation needed]

Stroke speed

[edit]

Stroke speed in facsimile systems is the rate at which a fixed line perpendicular to the direction of scanning is crossed in one direction by a scanning or recording spot. Stroke speed is usually expressed as a number of strokes per minute. When the fax system scans in both directions, the stroke speed is twice this number. In most conventional 20th century mechanical systems, the stroke speed is equivalent to drum speed.[56]

Fax paper

[edit]
Paper roll for direct thermal fax machine

As a precaution, thermal fax paper is typically not accepted in archives or as documentary evidence in some courts of law unless photocopied. This is because the image-forming coating is eradicable and brittle, and it tends to detach from the medium after a long time in storage.[57]

Fax tone

[edit]

A CNG tone is an 1100 Hz tone transmitted by a fax machine when it calls another fax machine. Fax tones can cause complications when implementing fax over IP.

Internet fax

[edit]

One popular alternative is to subscribe to an Internet fax service, allowing users to send and receive faxes from their personal computers using an existing email account. No software, fax server or fax machine is needed. Faxes are received as attached TIFF or PDF files, or in proprietary formats that require the use of the service provider's software. Faxes can be sent or retrieved from anywhere at any time that a user can get Internet access. Some services offer secure faxing to comply with stringent HIPAA and Gramm–Leach–Bliley Act requirements to keep medical information and financial information private and secure. Utilizing a fax service provider does not require paper, a dedicated fax line, or consumable resources.[58]

Another alternative to a physical fax machine is to make use of computer software which allows people to send and receive faxes using their own computers, utilizing fax servers and unified messaging. A virtual (email) fax can be printed out and then signed and scanned back to computer before being emailed. Also the sender can attach a digital signature to the document file.

With the surging popularity of mobile phones, virtual fax machines can now be downloaded as applications for Android and iOS. These applications make use of the phone's internal camera to scan fax documents for upload or they can import from various cloud services.

[edit]
  • T.4 is the umbrella specification for fax. It specifies the standard image sizes, two forms of image-data compression (encoding), the image-data format, and references, T.30 and the various modem standards.
  • T.6 specifies a compression scheme that reduces the time required to transmit an image by roughly 50-percent.
  • T.30 specifies the procedures that a sending and receiving terminal use to set up a fax call, determine the image size, encoding, and transfer speed, the demarcation between pages, and the termination of the call. T.30 also references the various modem standards.
  • V.21, V.27ter, V.29, V.17, V.34: ITU modem standards used in facsimile. The first three were ratified prior to 1980, and were specified in the original T.4 and T.30 standards. V.34 was published for fax in 1994.[59]
  • T.37 The ITU standard for sending a fax-image file via e-mail to the intended recipient of a fax.
  • T.38 The ITU standard for sending Fax over IP (FoIP).
  • G.711 pass through - this is where the T.30 fax call is carried in a VoIP call encoded as audio. This is sensitive to network packet loss, jitter and clock synchronization. When using voice high-compression encoding techniques such as, but not limited to, G.729, some fax tonal signals may not be correctly transported across the packet network.
  • RFC 3362 image/t38 MIME-type
  • SSL Fax An emerging standard that allows a telephone based fax session to negotiate a fax transfer over the internet, but only if both sides support the standard. The standard is partially based on T.30 and is being developed by Hylafax+ developers.

See also

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References

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Further reading

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